FI74179C - Teletext device with short page search time - Google Patents

Description

1 74179 TV text service device with low page retrieval time

The present invention relates to a side-by-side co-display arrangement during a data time period on a television display tube, the arrangement comprising an input circuit for receiving digital input signals transmitted together with the television signal and including image information displayed in coded form, page and line numbers, page one or more line image information the man-10 transmits a television signal for the duration of the field, the image memory input of which is connected to the output of the input circuit, the image memory being suitable for storing and remembering the coded image information of the page during said period of time; further comprising a background memory arranged to store the encoded data contained in the at least two pages and a control circuit for controlling the transmission of the digital input signals to the image memory and said memory; background memory.

Arrangements of the type described above can be used in television receivers to receive digital information signals which, during predetermined television line periods in which there is no television image information, are transmitted with the television signal by a television transmission station that is part of a teletext system and related systems.

Once the digital information signals have been filtered from the complete video signal by the input video processor, hereinafter referred to as TVIP, the input circuit can distinguish address portions such as page and line numbers from the image information codes. The transmitted digital information is transmitted periodically and repeatedly in the teletext service and similar systems, usually in divisions of a few tens of seconds.

2 74179

The control circuit ensures that as soon as the user queries a particular page, the image information codes associated with that page number are stored line by line in the image memory.

To display the page in question, the stored image is read, while the converter circuit converts the codes of the image information into video signals in a manner known per se by means of a character generator.

For example, if the repetition rate of the digital information is 30 seconds, the waiting time between the query and the filling of the image memory 10 is on average 15 seconds if no background memory is used. If this average waiting time also occurs in each successive query, the user will find this annoying.

This can be partially avoided by expanding the image memory to a background memory suitable for storing image information of two or more pages.

An arrangement of the type described above is disclosed in Dutch Patent Application No. 7704398. In this arrangement, the user must indicate via the control circuit 20 which pages he wishes to store in the background memory.

In the event that a user queries the next page based on the data contained in the index page without knowing in advance the need to retrieve that page, there is also an average waiting period of 15 seconds because that page is not stored in background memory.

It is an object of the present invention to provide an arrangement in which the average waiting time is reduced to almost zero after the first query without the user having to perform additional steps to control the background memory.

According to the invention, the arrangement is characterized in that the control circuit is arranged so that when a new page is queried, it is checked whether it is already stored in the background memory and, if so, the coded image information is transferred from the background memory to the image memory via the input circuit. in the background memory, the digital input signals are input to the input circuit until the interrogated page is identified in a manner known per se and written to the image memory, and the digital input signals are input to the background memory input so that the background memory must contain encoded data contained in multiple pages.

This is done as follows. The information displayed in the customer's teletext systems is divided into several groups, commonly referred to as magazines, each of which has its own index. The magazine comprises a maximum of one hundred pages.

For example, the background memory is selected to have a large enough capacity to store a large number of pages, preferably at least one full magazine. This background memory can, for example, be directly connected to a source of digital input signals, i.e. before the input circuit, so that the digital input signals are written continuously without selecting the background memory.

Another method of writing to the background memory is to enter information from the time when the queried page number in the received signal is identified until the time when the memory is full or partially full.

In this writing method, the choice of magazine can be influenced, if desired, by the magazine number that appears at the beginning of each line.

Neither of these methods requires additional control from the user or additional information from the transmitter.

. . For the first query, which is an index, for example, this index is written to the image memory after an average waiting time, after which this index can be displayed immediately. When the user reads the index, the background memory must be in a few seconds with digital input signals. The time period in which this occurs may depend on the capacity of the background memory and is selected, for example, by first writing the queried page to the background memory 4 74179 while writing the image memory, and then feeding the following pages until the background memory capacity is full. For example, the information stored in the background memory can be recorded in the register of the control circuit.

If the next user query is related to one of the pages thus written in the register, then the control circuit connects the input circuit to the background memory output, which as a result starts to act as a digital input signal source. The required in-10 information is now stored in the image memory in less than 0.1 second, which waiting time is so short that the user does not notice it. The contents of the background memory have not changed in this context. In practice, it has been found that a large proportion of consecutive queries always remain within the background memory content-15 so that a new wait period occurs only very rarely, namely when a user requests a page that has not yet been saved. It is also, of course, possible to make the background memory dimensioned so that all magazines can be stored perfectly. In this case, 20 there is never a waiting period after the first query.

The preferred embodiment of the invention is characterized in that the background memory is arranged such that during periods in which no information is written to the background memory, the encoded data stored in the background memory is always rotated at least once under the control of the background memory control circuit and the input circuit is switched to background memory output. which, in a manner known per se, identifies the page number of the page in question in the rotating information and transfers the coded image information associated with this page to the image memory.

The selection mechanism can then be very simple, as the input circuit is usually in standby mode until the queried page passes during this cycle, so that no separate re-registration of the pages included in the background memory needs to be performed. This does require a bit of waiting time, but it is not noticed because it is possible to recycle all the stored information in a short period of time.

A cost-effective solution is achieved if the back-up memory is an intermittent type of memory in which the storage of the stored 5 data cycles also aims to reload the contents of the memory, and in which the time periods during which no write or rotation occurs are shorter than the back-up memory time.

The solution can be found in integrated CCD memories (charge transfer registers), which already have the possibility to place more than 300 kilobits (308 x 1,024 bits) in a single integrated circuit. If each 1,024 bit unit is used to store three lines of text, each with 336 bits, 308 x 3:15 25 =: 37 pages can be stored in a single module, three modules will suffice for one full magazine. In practice, 40 pages or more can be stored in one module because most pages have less than 25 lines written.

20 However, the structure of the image memory is different. In the image memory, where each line of text has 40 symbol positions per line, only the image information codes, each consisting of one 8-bit byte, are stored on each line, i.e. 40 x 8 = 320 bits containing once per 25 pages a page number which in the first per line forms part of the image information code, but does not contain a 16-bit line number per line. Because the background memory can be placed before the input circuit, all digital information including line numbers is stored, so now 320 + 16 = 336 bits per line of text are needed, but on the other hand writing to the memory is simplified because the separation of number bits and image information bits has been made unnecessary. now completely replace the original digital input signal-35 lien source.

6 74179

The background memory may consist of different types of shift registers or alternatively, for example, a serial-to-parallel converter followed by an addressable memory in which w-bit "words" are stored in the 5-word address memory locations specified by the address counter in the control circuit. Also in the latter case, the combination acts as a serial memory during writing. One skilled in the art will be able to select any suitable type of memory for this purpose and this selection is not essential to the inventive idea.

The invention will now be described in more detail by way of example with reference to the accompanying drawings:

Figure 1 shows a simplified block diagram of the basic form of the arrangement according to the invention;

Figure 2 shows a block diagram of a practical embodiment;

Figure 3 shows the locations of the rows and their bits in the background memory; Fig. 4 shows a substantial part of the control circuit as used in the background memory during data storage and reloading operations;

Fig. 5 shows a timing diagram related to the circuit shown in Fig. 4; Fig. 6 shows a simplified block diagram of a background memory with only a magazine selection, and

Figure 7 shows a simplified block diagram of a background memory for magazine selection, comprising a second memory block for time compression.

30 Corresponding elements in the figures are denoted by the same :: reference numerals.

In Fig. 1, for example, the video signal from the receiving part of a television receiver is input to the input 1 of a TV text service input video processor 3 (TVIP), which processor is a conventional type for receivers suitable for a TV text service. The main purpose of TVIP is 7 74179 to filter out, in a manner known per se, the video lines of the TV text service which are transmitted during the vertical shutdown time of the jet and further feed them into the circuit as digital input signals (DIS) via output 5. The output 5 is connected to the first input 7 of the output 9, the output of which is connected to the input circuit 13 (ACQ) to the output 11, which in a manner known per se provides data collection of image information codes from the DIS associated with the page requested by the user. The picture information codes are stored in the picture memory 15, which is, for example, in the form of the direct access memory TRAM of the standard 10 teletext service device. In order to display the requested page on the image surface, the TRAM is read periodically and cyclically, the converter circuit 17 (DSP) generating the necessary video signals for the display and supplying them via the output 19 to a display circuit 15 not shown.

The output 5 of the TVIP is further connected to the input 21 of a serial background memory 23 (CCD), which memory consists of, for example, one or more integrated CCD registers. The output 25 of the background memory 23 is connected to the second input 27 of the switch 9, so that if the switch 9 is set to the position 27-10, the DIS stored in the CCD can be fed to the input circuit 13 via the input 11, after which it is processed in a manner known per se. is deposited in the CCD. .

The whole procedure is controlled by the control circuit 29. The ordinary control of the teletext service will not be discussed in more detail in this connection, some control functions essential to the present invention will be described below with reference to Figs.

30 For control, the circuit TVIP (3) supplies several timing signals, which are standard timing signals for the TV text service. TCLK output 31 inputs the nominal frequency. . 6.9375 MHz for the input signal control circuit 29 of the teletext TV service 41.

At the beginning of each period of the picture line of the TV text service, the SR output 33 supplies an OFF pulse "start line" to the corresponding input 43 and the DEW 'output 35 supplies a "data input window" signal to the corresponding input 45 of the control circuit 29.

The DEW signal is in the OFF state ("0") during the part of the vertical shutdown time of the jet during which the picture-5 lines of the TV text service are transmitted, i.e. usually during four or more picture period periods of 20 milliseconds each. During the field duration (or 1/60 second in NTSC countries), a write command is executed. Outside this time period, DEW 'is in the ON state ("1").

The user indicates his wish, for example, by means of a keypad 47 connected to the control circuit 29 via a signal link 49. The signal link 49 may be a wire connection, but for remote control it may alternatively consist wholly or partly of infrared light pulses or ultrasonic pulses.

The control signals transmitted by the control circuit 29 are schematically shown in their block diagram by means of a multi-channel connection 51.

When a new page is queried, the control circuit first checks whether this page is already stored in the background memory. If this is not the case, the switch 9 is set to the position 7-10 shown and the digital input signals DIS are fed to the input circuit each time during the DEW period.

There are several solutions to perform this inspection. For example, it is possible to write down in the secondary memory of the control circuit during the writing of the information which information is stored on the basis of the page and line numbers.

Since the entire background memory can be read in a fraction of 30 seconds, it is also possible without the user: to check the existence of the information retrieved from the background memory first when a new query occurs, read this information if it exists, and if not, browse incoming digital input-35 signals within the normal average wait time.

9 74179 In the latter case, the increase in the very small average waiting time is offset by the simplification of the control circuit.

During those parts of the field duration when the tele-5 vision signals are transmitted, DEW = 1 and the TV text service clock TSCLK is in an inactive state.

As soon as the requested page number has been identified by means of a circuit known per se and not shown in the drawings (ACQ), the storage of the image information of this page in the memory of the image-10 begins 15.

Although not necessary, the DIS is stored in the background memory continuously or can be started when a new query occurs. The deposit can start at the same time as the deposit in the image memory as soon as the page number is identified.

As soon as the queried page is stored in the TRAM (15), its display can be started while the background memo is still being written. If the background memory has a capacity of x lines, writing may end in the x-line period after writing to TRAM was started. This can be done in different ways. It is possible to calculate the x-pulse SR 'in the control circuit 29 or in case there are 4 TV text service lines per DEW period, x / 4 DEW' pulses can be calculated. Alternatively, it is possible to stop typing as soon as a predetermined larger page number has been identified. The exact location of the address identification is not essential to the invention. This can be implemented in both TVIP and ACQ. For this purpose, it is also possible to supply DIS to the control circuit 29 if the identification of the address 30 has been performed there.

When the write operation is completed, the DIS represents the number of pages in the background memory, thus including the line numbers, while the TRAM still contains the image information except for the line number of the queried page.

35 If the next query is for a page that has not yet been written, repeat the procedure described above.

10,741 79

However, in most cases, the following query was found to be on a page already stored in background memory 23.

In this case, the switch 9 is set to position 27-10, 5 after which the ACQ can obtain the requested page number in the TRAMs.

If the background memory 23 is not of the intermittent type, this transfer can be performed by pointing to the memory because the exact location of the requested page deposit is known. Alternatively, the information stored in the background memory 23 can be rotated, with the ACQ now waiting until the requested page passes. In this case, the background memory 23 acts as a completely different source of digital input signals, the only important difference being that the cycle period is preferably equal to the field duration minus the vertical jet-15 time, i.e. slightly less than 20 milliseconds, so that the average wait time exceeds 10 milliseconds. This is such a short time that the user will not notice it.

Figure 2 shows a practical embodiment of a serial memory 23 comprising one or more memory modules 20-64. In this example, each module is selected to be a CCD shift register with 315,394 bits arranged in series. Although there is no difference in the physical barrier, a simple structure is achieved by using a module with 308 groups of 1,024 bits each.

Each module has an input 67 and an output 69, which can be connected to each other by means of switches 71-75, respectively. In the position shown for these switches, each module is a rotary module and is not connected to any other module.

In this situation, the memory is reloaded periodically. Since this is always done once during the write cycles DEW, 308 x 1,024 transfer pulses must be applied in about 15 milliseconds for recharging at a time. These 315,392 transmission pulses in 15 milliseconds correspond to a transmission clock frequency of about 21 MHz. The SC signal of this shift clock 35 is fed to the shift clock input 80 by the control circuit 29.

i.

11 74179

To write background memory, switches 71-75 are set to another position during the DEW cycle. Modules 61-65 are thus arranged in series with each other. During the DEW period, the digital input signals DIS can be input to the input 67 of the first module 61 via the input 21, the memory input switch 81, the read switch 82, and the switch 71. Switches 81 and 82 are then in the position shown in Figure 2. The switch 81 is controlled from the control circuit 29 by means of a signal S1 which is fed to the input 83 of the background memory 23.

The writing operation can now be performed at the clock frequency of the TV text service, which thus also acts as a transmission clock for the modules 61-65, respectively.

If m = 4 TV text service lines are transmitted during the DEW period, 4 x 336 bits are written accordingly. Since the number 336 comprises a factor of 3, multiples of 1,024 are never obtained in this way, so that a situation is achieved in which N-1 rows of lines are distributed on the n-module, which are divided into two modules i and i + 1 (i = 1 , ... N). Thus, it is recommended to fill 20 each group of three rows with 3 x 336 = 1,008 bits to which 16 bits have been transferred, giving a total of 1,024 bits.

Alternatively, memory modules with 336 bit mono bits can be selected. However, the modules described here by way of example are less expensive because they are already used to store a normal television picture in digital form with 308 lines stored per 312.5 ri fields. If 512 elements with 14 bits each are stored per line, the seven such modules have exactly the capacity sufficient to store the entire information of the television field. The question is: of course, whether these types of modules are also used in the field of TV text service.

A surprisingly simple structure is achieved by synchronizing the shift clock with a frequency of about 21 MHz with the clock of the TV-text-35 service, so that the clock operates exactly three times at the clock frequency of the TV-text service, 12,741,7, i.e. 20.8125 MHz. In this situation, the switch 81 (S.) is controlled so that during each third part of the transfer clock it is in the position shown and in the second position at the other time of the cycle. At the clock frequency 5 of the TV text service, the transmission clock produces 1,024 pulses per line duration, so that at the end of the line duration, the first bit of the text line arrives in the last 1,024 bit group (imaginary), e.g., 1,021. Each stored bit is followed by two free transmission so that the second information bit is located at position 1 018 of the 1024 bit group, etc. Thus, the 336th information bit arrives at bit position 1 021 to 3 x 335 = 16. The remaining bit positions remain unfilled, Fig. 3, line AA. Thus, in order to fill the gaps, the information bits transmitted at the end of the module 15 are fed back to the input of the first module 61, the switch 81 being in the second position. Since the first bits of the line or text are always at position 1,021 at the end of the group, the old bit appears at the output 69 N of the module 65 at the same time as the new bit 20 is written, reaching this switch 81 when this switch is not in the position shown. To prevent this, a delay circuit 85 producing a time delay of one transmission period is arranged between the output 69-N and the switch 81. This can be accomplished in a simple manner by expanding the size N x 308 x 1024 bit transfer register by adding a transfer clock controlled flip-flop 84 via the transfer clock input 86.

It is obvious that the bits that were originally written to bit positions 1, 4, 7, 10, etc. are now written after the transit of all 30 modules and one time delay bit: to bit positions 2, 5, 8, 11, etc. and after the second transit to positions 3, 6, 9, 12, etc. The entire transfer register is completed at the end of the third transit (Figure 3, lines BB and CC).

35 Assuming N = 3, a total of 3 x 3 x 308 = 2,772 rows are now stored. The first bit of line 2,772 is 13,741,79 stored in the 1,024 bit group of the first module's 1,024 bits and in the 36,166 bit bits of that 16 bit line of this group. Then the first bit of the 2 771th row is stored in the 10 021st bit of the second 1 024 bit group of the first module, etc., finally, the first bit of the 1 849 row is stored in the 1021st bit of the 308th group of the third module. The information of line 1 848 was previously stored in this group, but has during this time moved to the first group of module 1, by one position, so that bit 1 is in bit 1020 and bit 336rdes is in bit position 15. Bit positions 0-13, 1 022 and 1,023 are unoccupied in all 3 x 308 groups.

Figure 4 shows an example of a part of the control circuit which is essential to the invention and produces the required timing signals during write and reloading of the background memory. Its operation will be described with reference to the timing diagram of Fig. 5, in which the lines of the timing diagram refer to the names of the signals and counters as they appear in Fig. 4 and the following description.

The control circuit first comprises a clock generator circuit 91 (CG) which produces a clock signal having a frequency in the idle state of about n times the frequency TCLK of the TV text service clock, where n is an integer. The clock generator 91 can be synchronized with respect to TCLK via input 41 in such a way that its frequency becomes exactly equal to n times the TCLK frequency. In the example described, n = 3, but this is not relevant to the invention. The clock generator 91 supplies the clock signal CLKn to the first input 93 of the AND gate 95, which has an output 97 for the transmission coil signal SC at the clock circuit output 99.

In addition, the signal is applied by the SC 1024 to the input 101 of the divider 103, which is, for example, in the form of a CTR 1 of a 10-bit counter. In this example, it is assumed that all-0 ki counters change state when the edge of the signal changes from 35 ON to OFF. In the signal drawings of Figure 4, ON is located, is always at the top, and OFF is at the bottom. All 14,741,79 counter elements have reset inputs R ', through which the counters can be reset to the 0 state and maintained in the 0 state as long as R' = 0.

The output signal of the counter 103 is applied to the input 105 of the counter 107 of the state 5, which may be in the states 0-309. The counter 107 outputs 109 for the output signal ER ', which is in the ON state in the calculation states 0-308 and in the OFF state in the calculation state 309. The ER' output is connected to the second input of the AND gate 95.

In this example, the counter 107 is in the form of a 9-bit counter with a first flip-flop 115, eight subsequent flip-flops 117, and an AND-gate 119 for decoding the counter state 309. The output of the AND gate 119 comprises the output 109 of the counter 107. The output for the output signal Q '^ is connected to the output 121 of the counter 107. Q' ^ = 1 when the content of the flip-flop 115 is 0, i.e. for all even states 107. Q '^ = 0 for all odd states.

The signal Q '^ is applied to the first input 123 of the OR gate 125, the second input 127 of the gate of which is connected to the input 45 of the control circuit 20 for DEW'. The output 129 of the OR gate 125 is connected to the third input 131 of the AND gate 95.

The shift clock signal SC is further input to the input 133 of a three-state counter 135, which has an output 137 for the output signal Q4. In this example, the three-state counter 135 is formed in a manner known per se by two JK flip-flops 139 and 141, which counter has an intake 143 for the intake of the first flip-flop 139 and a reset intake 145 for each flip-flop. When the inputs 143 and 145 are both in the ON state, the counter 135 passes in a rotating order through the following three states: "0" = where Q3 = 0, Q4 = 0; "1", where Q3 = 1, Q4 = 0; and "3", where Q3 = 1, Q4 = 1.

Finally, the signal SC is applied to the first input 147 of the AND gate 149, the second input 151 of the gate is connected to the output 137 of the three-state counter 137. The output 153 of the control circuit 29 15 741 79 is formed by the output of the AND gate 149 to supply the SI signal to the input 83 of the background memory. is in the ON state when SC and Q4 are both in the ON state, i.e., each time the counter 135 is in the "3" state.

The left half D-E of Fig. 5 shows the variations of the signal count states when writing DISs to the background memory, the right half E-F shows these variations in reloading the information into the background memory. Writing is always performed during the DEW cycle, so DEW = 1 and DEW '= 10 0. In response to DEW', the eighth flip-flop 117 of the counter remains in the zero state, so that ER '= 1, so the second input of the AND gate 95 is in the ON state throughout. during the writing period. At the beginning of the first line of images during the DEW period, a signal start line (SR1 = 0) is produced, which causes the counter 103, the flip-flop 115 15 and the counter 135 to return to the zero state. As a result, Q'1 = 1 and the first input 123 of the OR gate 125 is ON. The second input 127 remains in the OFF state in response to DEW '= 0. The output 129 is in the ON state and correspondingly also the AND-ve-. . the first input 131 of the gate 95. In this state 20 of the AND gate 95, each pulse of the clock generator CLK results in a pulse SC. During the DEW period, the clock generator synchronizes with the TCLK to a frequency three times the clock frequency of the TV text service.

It now follows 1,024 transmission clock pulses SC, to which counter 103 counts from 0 to 1,023 and then further drops to zero. Moving from 1,023 to 0, the flip-flop counts so that the next counter 107 is adjusted. 1 state, where Q'1 = 0. In response, the first input 131 of the AND gate 95 is set to OFF so that no more 30 SC pulses are produced. During the first 1 024 SC pulse, the SI is set to ON in response to every third SC pulse, so that bits 1/1 to 1/336 of the digital input signals of the first frame of this DEW period are written via switches 81 and 71 of the background memory (Fig. 2). fractionally to the locations marked with AA in the background memory in Figure 3.

16,741 79

After the next new SR ', the writing procedure is repeated starting from the first bit 2/1 of the second picture line until the last bit m / 336 of the last picture line m of the DEW period is stored. Now no new SR 'arrives forward-5, so that counter 303 remains in the zero state, Q'1 remains in the OFF state until the end of the DEW period. Immediately after moment E, the DEW 'signal is turned ON and the memory recharge cycle begins. When the DEW 'is equal to 1, the output 129 of the OR gate 125 and the third input 131 of the AND gate 95 10, respectively, come ON so that the SC pulses are produced again. The state of the signal Q '^ is not important to the OR gate 125 as long as DEW' = 1 maintains the input 125 in the ON state.

At the beginning of the recharging cycle, the counter 107 is in one state. After 1 024 SC pulses, it is set to "2".

After 15 308 x 1024 SC pulses, the counter 107 finally has a state sa "309", then ER 'becomes equal to 0 and the second input 111 of the AND gate 95 is set to OFF, so that no new transfer clock pulses SC are produced. . When the 308 x 1024 SC pulses are rotated, all modules M ^ -Mn 20 are rotated exactly once, as required in the recharging cycle. During this time period, the clock generator CG (91) operates in an asynchronous state at a frequency which is about three times the frequency of the TV text service or slightly higher, for example 21 MHz. 308 x 1,024 SC pulses then require 25,308 x 1,024: 21 = 15 ms. Thus, the reload operation is completed before a new DEW cycle begins after the field duration. In the next DEW period, the (n + 1) / th bit of the (m + 1) line of the text begins to be written. The control circuit 29 continues this procedure until a maximum of 2,772 30 lines of text have been written.

During recharging, the output of the background memory switch 81 is not connected to the module, so the state of the switch 81 is irrelevant. Thus, it is possible for the counter 134 to continue counting during the recharging period, so that the pulse 35 S1 is generated in response to every third pulse SC.

= "1" or = ER 'sufficient.

17,741 79

The circuit described is presented only as an example to find out how different time periods can be implemented by means of counter circuits. One skilled in the art will be able to design many modifications of this, in which the choice of different types of flip-flops, for example D-flip-flops, is possible. The same times can be implemented just as easily if the calculation operation is continued with the rising leading edges of the pulses or with the pulses themselves. If it is ensured that in the switch-on situation, the counter 103 is set to zero, then the reset operation at a later time 10 is not necessary, because the counter in question always stops to zero.

If a different number of M-modules is selected in the background memory, 3 x 380 x N rows can of course be stored. When N = 7, a maximum of 6,468 lines can be written, which is enough for about 320 pages, with an average of 20 lines per page, ie more than three magazines.

Once the background memory is written, the lines of one page are stored in successive groups of 1,024 bits, usually located in one module. Thus, the first rows 1-20 of ky-20 in this example are located in groups 308-289, respectively in the Nsnne module.

There are several methods for reading back the stored information.

For this purpose, Fig. 2 shows a circuit-25 161, one side of which is connected to the outputs 69 to 69-N of the M-modules and the other side is connected to the output 25 of the background memory.

In the reading circuit, the control circuit selects, for example, the input corresponding to the module in which the first 30 lines of the queried page are stored, or the selection circuit takes samples, for example sequentially, of the module outputs. When the reload cycle is completed, a read is performed every third bit and information is input via output 25 and switch 9 to input 11 of input circuit 13, which circuit receives 35 bits at a frequency of about 7 MHz, which is approximately equal to the normal TV text service frequency. . The information of the queried IE 74179 lines is transferred to the image memory 15 in the conventional manner until the next larger page number is indicated. Since the reload operation is repeated every 20 milliseconds, the average waiting time is about 10 ms, which is 5 so small that it can be considered insignificant. In some cases, the last lines of the page are included in the previous module. If module group 1 has been read without a new page number being indicated, the selection circuit changes to this previous module. Every third bit is read, for example, by a switch Soff ', not shown, which is controlled in the same way as a switch S ^ n (81). For this purpose, the states "0", "1" and "3" of the counter 135 are coded, the switching circuit connecting the switch to the decoding device that produces the queried lines for output 15 25. Figure 3 shows that, for example, all lines 1 838-1 667 occur in group states with position numbers equal to the three groups whose bits occur after X x 1024 + Y x 3 pulses in module output. For the mode to be decoded, a code corresponding to x-modulo 20 3 is selected.

A simpler structure is achieved if, before reading all switches 71-75 from the background memory, the read switch 82 is set to another state and the reload operation is performed once with N x 308 x 1024 with the shift clock pulse SC 25 and connected to the counter 135. The reading circuit is now connected to only one of the outputs 68-69 -OF. The entire information of all modules is now traversed in N x 15 milliseconds, i.e. if N = 7 in total in about 105 milliseconds. The simplified structure thus results in an average waiting time of about 52.5 milliseconds, i.e. about 1/20 second, for the page in question, which is still hardly noticeable.

It is obvious that after the N x 308 x 1024 SC pulse, the whole background memory is once again reloaded once and all the information is in exactly the same places. 35 In this case, the counter 107 must be expanded so that it can have N x 308 + 2 positions of space when N = 7 must |.

19,741 79 end of reloading to state 2,157 with counter 107 being expanded by two bits to 11-bit.

In this situation, the signal ER 'must then be reconnected to the output of the AND gate 119 and to the output of the second AND gate 5, which is not shown, in order to decode the state 2 157. At least during this time period, counter 135 Soldering must be ON. As already described above, the input 143 may be continuously ON or it may alternatively be connected to the signal ER '.

10 The structure of the reading circuit and the modification of any of the described circuits can be designed by a person skilled in the art by means of accessories which are known per se.

As mentioned above, the arrangement according to the invention can also be used in different ways. Namely, it is alternatively possible not to stop writing the background memory 23 as soon as all the groups have been filled, but to continue writing after that.

In the example using three modules, it is obvious that if the next 20 lines are written after the 2,772th line, the latter deletes the first line. From now on, the oldest information is always erased. Since the information obtained is subject to change, it is a pure coincidence whether the next query page is included or not in the background memory at the time of the query. However, the average-25 rin is stored at 2,772: 20 = 130 pages. For example, if the total number of TV text service pages is 195 pages, there is no waiting time at all in 130 of the 195 queries. The remaining 65 possible queries, always for those pages that are about to enter, have a time period equal to 65/195 = 1/3 of the replay period of the TV text service, so the average wait time is: 1/6 of it . With a repetition period of about 30 seconds, the average waiting time in 65 of the 195 random queries is thus 1/6 x 30 = 5 seconds. For a total of 195 queries, a 5-second waiting time occurs on average 65 times and a substantially zero waiting time occurs 130 times, 20 7 4 1 79 so the average average waiting period is about 1.7 seconds with a maximum time of 10 seconds.

In the case described above, the waiting time for already saved pages is also "zero", but for fewer queries on non-saved pages, the waiting time is on average 15 seconds and up to 30 seconds. The second method is usually more advantageous if the ratio of the number of pages that can be stored to the total information content of the teletext service exceeds about 0.5. So this pre-10 character is suitable for a case with three modules and a 195 page supply, but not for a 3 module and 800 page supply.

If the back-up memory can be selected so large that the entire supply can be stored, then in both cases the waiting time always becomes "zero" after the first-15 queries, so then both methods are of equal value.

Except that in the second method used, writing is not stopped after N x 30 x 308 lines of text have been stored, the other steps during writing, reloading, or reading are completely identical to the steps described in the first method used.

It also applies to both methods used that the existing standards of integrated circuits 3, 13, 15 and 25 17 are suitable for TV text service processing without any modification.

The control circuit 29, the switch 9 and the switching elements of the serial background memory 23 (except for the memory modules 61-65) can be combined in one new integrated circuit 155 (Fig. 1).

In Figure 6, the background memory consists of one or more memory modules 601, 602, 603 having sufficient memory capacity to store digital input signals DIS associated with a full hundred-page magazine. These DIS-35 signals are input to the signal input 607 of the first selection circuit 609 via the electrical circuit 605.

i 2i 74179

In the same manner as described above, the first selection circuit 609 serially connects the modules 601, 602, 603 of the first write period DEW (data input window during the part of the duration of the television field) via the connections 51111, 612, 613 and 614. Outside the DEW, if the memory is of the recharge cycle type, the outputs of the modules are connected to the inputs of the circuits 611, 610; 613, 612 and 615, 614.

The second selection circuit 619 has inputs 621, 622, 623 for the output signals of the modules 601, 602, 603 in the respective circuits 611, 613 and 615 and an input 625 for the DIS signals connected to the circuit 605. The output 627 of the second selection circuit 619 is connected to the input circuit 631 (ACQ) 629 to read the contents of the background memory.

15 Through a control element and a control circuit (not shown), the user selects the desired page number, as a result of which the page mute signal PS is applied in a manner known per se to the electrical circuit 633 to supply the PS to the auxiliary input 635 of the input circuit 631. the text service device was known for components such as a picture memory, a character generator and a video signal generator.

In addition, the background memory has in its input 605 for DIS signals a magazine selection circuit 641 (MSC) having a DIS-25 input 643 and a PS input 645. The output 647 for the magazine selection signal MS is connected to the selection input of the first selection circuit 609.

The background memory works as follows. If a page is queried, the second selection circuit 619 connects the input circuit 631 itself to the memory modules in a sense-30 manner to determine whether the DIS associated with the queried page is stored in memory.

As described above, this can be accomplished, for example, by serially connecting the input circuit to the memory modules 601, 602, or 603 for a duration of 35 consecutive fields and a recharge cycle. If the interrogated DIS is detected, the input circuit 631 carries the encoded image information 637 from these DIS line numbers 22 741 79 for further processing. The second selection circuit 619 then switches the input circuit input 629 to the second selection circuit 619 input 625 for the D1S signals until a new page is queried. In this situation, the input circuit 631 continues to check the DIS signals for the data associated with the selected page, so that, for example, changes between the contents of these pages are monitored.

In prior art systems, such as 10 teletext devices and related systems, the number of the queried page is formed from three characters, the first of which represents the magazine number.

If it is found that the searched information is not stored in the background memory, then the information is derived from the en-15 sin DIS signals via paths 605, 625, 519, 627 and 629 and the information reaches input circuit 631 with an average wait time of 10-15 seconds depending on your TV text service. the total transmission time of the supply.

In addition, the page number is received by the magazine selection circuit 641. This magazine selection circuit compares the first character of the requested page number at the beginning of the TV text service image line during the DEW period with the magazine number contained therein. If these magazine numbers match, a magazine selection signal MS is generated and input to the selection input 649 of its first selection circuit 607. The magazine selection signal MS remains in the "ON" state until a different magazine number is detected from the following characters, commonly referred to as "page titles" ( always page line 0).

During DEW cycles in which the MS is "ON", this DIS is written in a manner known per se to the memory modules, which are then arranged in series. As soon as one complete transmission cycle has taken place, all rows related to background memory are included in the selected magazine. The next query on the side of the same magazine is then always acknowledged within three field cycles, i.e. the average waiting time is about 1.5 x 20 = 30 ms, which is so short that it is invisible to the user.

I, 23 741 79

Since, in reality, a magazine usually does not reserve a hundred full pages, the DIS signals of the selected magazine continue to be written until a query to the next different magazine page, so that after some time the entire background memory is externally filled with information related to that magazine, it being possible that the same information occurs two or more times in different memory locations.

Since the magazine number is represented by an eight-bit 10 Hamming code, the decision as to whether the information needs to be written to memory can only take place after the bit period of the eighth TV teletext service device after the beginning of this symbol. Since the symbol itself must also be memorized while the line under consideration belongs to the searched magazine-15, a magazine selection circuit 641 includes a write time delay circuit that provides a time delay of at least eight bit periods of the TV text service device for the signal to be memorized. These write time delay circuits are known per se. In most cases, a shift register is used for this purpose, which in the present case must have at least eight shift elements.

Figure 7 shows a larger background memory comprising N memory modules. In Fig. 7, the elements correspond to -25 corresponding to those denoted by the same reference numerals in Fig. 6.

The first selection circuit 659 and the second selection circuit 669 are expanded to correspond to a larger number of memory modules.

The first part of the N memory modules is formed of, for example, three modules 601, 602 and 603, as shown in Fig. 6. During the DEW period, as is also the case in Figure 6, the output of the third module 603 is connected to the input of the first module via elements 615, 659 and 610. 35 As in the previous case, outside the DEW period, the outputs of all modules are connected to the inputs via connections 24 741 7 9 611-610, etc. to 665-664. As is the case in the arrangement shown in Figure 6, modules 601, 602 and 603 are used to select the magazine. The state of operation is the same as described with reference to Fig. 6.

The second part of the background memory comprises modules (651) to »n (653), the output of the last module 653 being connected during the DEW period to the input of the module 651 via elements 665, 659 and 660. The second part of the background memory is suitable for storing information related to non-selected macasi-10 and which operates as long as the signal MS at the input 649 of the first selection circuit 659 is in the "OFF" state, in the same way as described in the above-mentioned patent application.

When reading information from memory, the second selection circuit 659 operates in the same manner as described in the aforementioned patent application.

After the run period, the first part of the background memory is completely filled with the DIS information related to the last selected magazine, the second part always contains a part of the future 20 magazines, which part is not known in advance.

For example, if the total number of TV text service pages is 300, the following situation occurs. Each of the seven modules mentioned in this example may contain an average of 37 s.

For example, if the selected magazine comprises 60 pages, this magazine is fully included in modules 601, 602 and 603, in part in duplicate.

Of the remaining 240 pages, 4 x 37 = 148 are stored, more specifically the pages sent by the last transmitter 30.

In most cases, the following query is related to a previously selected magazine. As in the case of Figure 6, this query is acknowledged without a significant waiting period.

35 If the next query is for a page in a different magazine, then there is a probability 148/240 that 25 7 4 1 79 this page is stored in another part and even then the query is acknowledged with the same imperceptibly short waiting time.

In the remaining cases, the query is directed to information that has not been transmitted just before and is accordingly transmitted directly or substantially directly after the query. This means that 94 of the 300 possible queries have an average wait time of 47/300 times the transmission period of about 30 seconds, i.e. about 4.7 seconds. Since most of the queries 10 fall into the first group, the average waiting time overall is only in the order of one second.

In the example above, it is apparent that two modules would have been sufficient to store 60 pages of the selected magazine.

A further possible extension, also shown in Fig. 7, makes it possible to apply the feedback field in the first selection circuit 659 in such a way that in the latter example the output 613 of the module 602 is connected to the input 610 of the module 601 during the DEW period and so that in this example the second part of the background memory now consists of 5 modules with the remaining 240 pages to store the amount 5 x 37 = 185.

The arrangement comprises a page number identifier circuit 671 (PNR) having an input 673 for DIS signals and an output 675 for a code representing the magazine number and the page number, which codes are transmitted as page headers. These codes are input to the address input 677 of the random access memory 679 (RAM), which has at least 800 memory addresses with one bit stored in each.

30 With each new TV channel selection, the contents of all 800 addresses are set to 0.

As soon as the page number is identified, for example magazine 6 page 17, "1" is written to memory address 617.

If the magazine 6 contains 60 pages, then after some time 35, at the latest after one transmission cycle period, 60 of the 100 addresses 600-699 contain the status "1".

The readout 681 of the RAM 679 is connected to the count input 683 of the counter circuit 685, which circuit comprises, for example, eight counters 687-1 to 687-8. After some time, all counters have a counting mode representing the page numbers of the respective magazines, in this example counter N6 (687-6) has reached the state "60", because in each group of 100 memory addresses the number of ones is always counted. This calculation operation is performed periodically, for example every other field duration, so that if the content of the makin-10 bus increases on the transmission side by one or more pages, the calculation mode is adapted to a new larger number of pages.

When a new page is queried, the first selector circuit 659 is connected via signal circuit 629 and module select input 15 691 to the counter corresponding to the magazine number, in this case to counter 687-6. If the counter state is less than 37 or, taking into account the safety margin less than 35, reserve the first selection circuit 659 only for module 1 magazine selection, because feedback path 20 610-611 now continuously exists during and outside the DEW period and feedback path 665 is available for the second part. 612 During the DEW cycle.

If the calculation mode is "60", as selected in this example, two modules are reserved, as described above.

25 When the calculation mode is greater than "74" (or "70", for example), the first three modules are reserved for magazine selection. The remaining modules are always used for time compression only, which occurs because when the stored information is read, this reading can be performed continuously, rather than reading only during a small DEW portion of the field duration, as is the case with a TV text service device without no background memory.

In the simplified embodiment, it is possible to reduce the capacity of the RAM 679 to 100 per address location, 35 then the computing circuit 685 comprising only one counter 687. In this case, only the pages of the selected magazine 27 7 4 1 79 are counted. The first selection circuit 659 begins by allocating one module. As soon as the calculation mode exceeds the selected value "35" to "37" or the value "70" to "74", one module (2 or 3, respectively) is added to the reserved modules, thus taking a slightly longer period of time before the larger magazine is deposited. in the correct order to the magazine block.

If the selected magazine is small, for example 30 pages out of 300 pages, so that the allocation of one module is sufficient to select 10 magazines, then 6 x 37 = 222 pages out of the remaining 270 pages can be stored, thus further achieving a larger average waiting time reduction, wherein the three modules are permanently reserved for magazine selection.

15 It is obvious that variable allocation is already possible when using a background memory with a capacity of at least 100 pages, in the present situation three modules, 1, 2 or 3 modules reserved for magazine selection depending on the size of the selected magazine and 2, 1 or 0 20 modules respectively used for time compression.

It is also obvious that the invention is not only applicable to TV text service receivers, but can be applied equally well to receivers of similar systems such as Antipe, Telido and the like.

Claims (15)

28 741 79 An arrangement for side-by-side display during a data period on a television display tube, the arrangement comprising an input circuit for receiving digital input signals transmitted together with the television signal and including image information displayed in coded form, page and line numbers, one or more rows of image information -10 for the duration of the broadcast signal field, an image memory coupled to the input of the input circuit, the image memory being suitable for storing and memorizing the encoded page input information during said time period, converting the encoded image information is arranged to store at least two pages of coded data and a control circuit for controlling the transmission of digital input signals to the image memory and said background memory, characterized by 2 0 that the control circuit (29) is arranged such that: for a new page query, it is checked whether it is already stored in the background memory (23) and, if so, the coded image information is transferred from the background memory (15) via the input circuit (13); a new page not stored in the background memory is input digital input signals to the input circuit until the queried page is identified in a manner known per se and written to the image memory, and the digital input signals are input to the memory input so that the background memory is accessed by encoded data from multiple pages. An arrangement according to claim 1, characterized in that the control circuit comprises a secondary. memory to remember the pages stored in the background memory when writing encoded data. An arrangement according to claim 1, characterized in that the background memory consists of a serial-to-parallel converter and an addressable memory having a word length of 29 7 4 1 79 w-bits, the serial-to-parallel converter always combining w consecutive bits of the serial input signal into its memory word and writing to the memory locations selected by the memory control circuit. An arrangement according to claim 1, characterized in that the background memory is a serial memory and is arranged such that during time periods when no writing is made to the background memory, the encoded data stored in the background memory is rotated at least once in the background memory under the control circuit 10 control. and identified in a manner known per se in the page number circulating information of this page, and the encoded image information associated with this page is transferred to the image memory. An arrangement according to claim 4, characterized in that the serial background memory is an intermittent type memory, wherein the recycling of the stored data also reloads the contents of the memory, and wherein the time periods in which no information is stored or recycled may be shorter than the time period, the information disappears from the background memory. An arrangement according to claim 4, characterized in that the background memory consists of two or more serial sub-memories which are arranged in series during writing and during a period in which no writing is performed, are separated so that the encoded data stored in the sub-memory rotates only in this sub-memory and also comprises a selection circuit arranged so that the outputs of the sub-memories: * 30 are correspondingly connected to the input of the input circuit during a time period in which no writing is performed. An arrangement according to claim 4, characterized in that the background memory consists of two or more serial sub-memories arranged in series with each other during the writing operation and disconnected during the time period 74179, wherein the writing is not performed so that the sub-memory is stored. the encoded data circulates only in this sub-memory and also comprises a selection circuit arranged so that, during reading from the background memory, the control circuit switches the output of the sub-memory containing the requested side data to the input of the ot-circuit. An arrangement according to claim 4, characterized in that the serial background memory is suitable for an internal transmission frequency n times the bit frequency of the digital input signal, the control circuit comprising a clock generator circuit for this n times the frequency of the clock generator synchronized to the memory in the background memory at a bit rate and further comprising a switch which, during each nth period of the n-fold clock signal, switches the serial background memory input to the digital input signal and during the intervening (n-1) periods to the output of the time delay circuit whose input is connected to the serial background memory output. An arrangement according to claim 8, characterized in that the time delay circuit produces a time delay equal to the time of one clock cycle of the clock signal generator for an n-fold frequency. Arrangement according to any one of the preceding claims 25, characterized in that the back-up memory has digital input signals when the magazine selection circuit recognizes the maximum number at the beginning of each line of coded data and a deposit switch controlled by the magazine selection circuit, the output of which is connected to the background memory the digital input signals associated with the selected magazine are stored in the background memory. The arrangement of claim 10, wherein the first portion of the background memory is arranged to store digital input signals of the selected magazine 35, characterized in that the background memory has a second portion of digital input signals storing digital input signals coupled to a time compression input of the memory input switch. some of the digital input signals associated with magazines other than the selected magazine. An arrangement according to claim 11, characterized in that the background memory consists of a plurality of memory modules, of which at least the first module is for magazine selection and at least one other module is connected to the first module by the magazine selection circuit if the selected magazine data exceeds the module capacity and is otherwise connected to the background memory. to the second part. An arrangement according to claim 12, characterized in that the magazine selection circuit comprises at least a computing circuit for calculating the number of pages in one magazine, the computing circuit generating a sum signal if the number of computed pages in the selected magazine is at least substantially equal to the first module page capacity -20 to connect at least one other module to the first module. I An arrangement according to any one of the preceding claims, characterized in that digital input signals are continuously written to the background memory and during their occurrence. An arrangement according to any one of the preceding claims 1 to 13, characterized in that the data acquisition signals are written to the background memory for a certain period of time starting from the presence of the requested page in the digital input signals. 74179